drivers/pinctrl/pinctrl_mci_io_mux.c - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright 2022 NXP
  *
  * SPDX-License-Identifier: Apache-2.0
  */

 #include <zephyr/drivers/pinctrl.h>
 #include <soc.h>

 static MCI_IO_MUX_Type *mci_iomux =
 	(MCI_IO_MUX_Type *)DT_REG_ADDR(DT_NODELABEL(pinctrl));

 static SOCCIU_Type *soc_ctrl =
 	(SOCCIU_Type *)DT_REG_ADDR(DT_NODELABEL(soc_ctrl));
 static AON_SOC_CIU_Type *aon_soc_ciu =
 	(AON_SOC_CIU_Type *)DT_REG_ADDR(DT_NODELABEL(aon_soc_ctrl));

 /*
  * GPIO mux option definitions. Stored as a static array, because
  * these mux options are needed to clear pin mux settings to
  * a known good state before selecting a new alternate function.
  */
 static uint64_t gpio_muxes[] = {IOMUX_GPIO_OPS};

 /*
  * Helper function to handle setting pin properties,
  * such as pin bias and slew rate
  */
 static void configure_pin_props(uint32_t pin_mux, uint8_t gpio_idx)
 {
 	uint32_t mask, set;
 	volatile uint32_t *pull_reg = &soc_ctrl->PAD_PU_PD_EN0;
 	volatile uint32_t *slew_reg = &soc_ctrl->SR_CONFIG0;
 	volatile uint32_t *sleep_force_en = &soc_ctrl->PAD_SLP_EN0;
 	volatile uint32_t *sleep_force_val = &soc_ctrl->PAD_SLP_VAL0;

 	/* GPIO 22-27 use always on configuration registers */
 	if (gpio_idx > 21 && gpio_idx < 28) {
 		pull_reg = (&aon_soc_ciu->PAD_PU_PD_EN1 - 1);
 		slew_reg = (&aon_soc_ciu->SR_CONFIG1 - 1);
 		sleep_force_en = &aon_soc_ciu->PAD_SLP_EN0;
 		sleep_force_val = &aon_soc_ciu->PAD_SLP_VAL0;
 	}
 	/* Calculate register offset for pull and slew regs.
 	 * Use bit shifting as opposed to division
 	 */
 	pull_reg += (gpio_idx >> 4);
 	slew_reg += (gpio_idx >> 4);
 	sleep_force_en += (gpio_idx >> 5);
 	sleep_force_val += (gpio_idx >> 5);
 	/* Set pull-up/pull-down */
 	/* Use mask and bitshift here as opposed to modulo and multiplication.
 	 * equivalent to ((gpio_idx % 16) * 2)
 	 */
 	mask = 0x3 << ((gpio_idx & 0xF) << 1);
 	set = IOMUX_PAD_GET_PULL(pin_mux) << ((gpio_idx & 0xF) << 1);
 	*pull_reg = (*pull_reg & ~mask) | set;

 	/* Set slew rate */
 	set = IOMUX_PAD_GET_SLEW(pin_mux) << ((gpio_idx & 0xF) << 1);
 	*slew_reg = (*slew_reg & ~mask) | set;

 	/* Set sleep force enable bit */
 	mask = (0x1 << (gpio_idx & 0x1F));
 	set = (IOMUX_PAD_GET_SLEEP_FORCE_EN(pin_mux) << (gpio_idx & 0x1F));
 	*sleep_force_en = (*sleep_force_en & ~mask) | set;
 	set = (IOMUX_PAD_GET_SLEEP_FORCE_VAL(pin_mux) << (gpio_idx & 0x1F));
 	*sleep_force_val = (*sleep_force_val & ~mask) | set;
 }

 static void select_gpio_mode(uint8_t gpio_idx)
 {
 	uint64_t gpio_setting = gpio_muxes[gpio_idx];
 	volatile uint32_t *flexcomm_reg = &mci_iomux->FC0;

 	/* Clear flexcomm settings */
 	flexcomm_reg += IOMUX_GET_FLEXCOMM_CLR_IDX(gpio_setting);
 	*flexcomm_reg &= ~IOMUX_GET_FLEXCOMM_CLR_MASK(gpio_setting);
 	/* Clear fsel settings */
 	mci_iomux->FSEL &= ~IOMUX_GET_FSEL_CLR_MASK(gpio_setting);
 	/* Clear CTimer in/out, if required */
 	if (IOMUX_GET_SCTIMER_IN_CLR_ENABLE(gpio_setting)) {
 		mci_iomux->C_TIMER_IN &=
 			~(0x1 << IOMUX_GET_CTIMER_CLR_OFFSET(gpio_setting));
 		mci_iomux->C_TIMER_OUT &=
 			~(0x1 << IOMUX_GET_CTIMER_CLR_OFFSET(gpio_setting));
 	}
 	/* Clear SCTimer in/out, if required */
 	if (IOMUX_GET_SCTIMER_IN_CLR_ENABLE(gpio_setting)) {
 		mci_iomux->SC_TIMER &=
 			~(0x1 << IOMUX_GET_SCTIMER_IN_CLR_OFFSET(gpio_setting));
 	}
 	if (IOMUX_GET_SCTIMER_OUT_CLR_ENABLE(gpio_setting)) {
 		mci_iomux->SC_TIMER &=
 			~(0x1 << (IOMUX_GET_SCTIMER_OUT_CLR_OFFSET(gpio_setting) + 16));
 	}
 	/* Clear security gpio enable */
 	mci_iomux->S_GPIO &= ~(0x1 << (gpio_idx - 32));
 }


 int pinctrl_configure_pins(const pinctrl_soc_pin_t *pins, uint8_t pin_cnt,
 			   uintptr_t reg)
 {
 	volatile uint32_t *flexcomm_reg;
 	volatile uint32_t *iomux_en_reg;

 	for (uint8_t i = 0; i < pin_cnt; i++) {
 		flexcomm_reg = &mci_iomux->FC0;
 		iomux_en_reg = &soc_ctrl->MCI_IOMUX_EN0;
 		uint32_t pin_mux = pins[i];
 		uint8_t gpio_idx = IOMUX_GET_GPIO_IDX(pin_mux);
 		uint8_t type = IOMUX_GET_TYPE(pin_mux);
 		/*
 		 * Before selecting an alternate function, we must clear any
 		 * conflicting pin configuration. We do this by resetting the
 		 * pin to a gpio configuration, then selecting the alternate
 		 * function.
 		 */
 		select_gpio_mode(gpio_idx);
 		switch (type) {
 		case IOMUX_FLEXCOMM:
 			flexcomm_reg += IOMUX_GET_FLEXCOMM_IDX(pin_mux);
 			*flexcomm_reg |=
 				(0x1 << IOMUX_GET_FLEXCOMM_BIT(pin_mux));
 			break;
 		case IOMUX_FSEL:
 			mci_iomux->FSEL |=
 				(0x1 << IOMUX_GET_FSEL_BIT(pin_mux));
 			break;
 		case IOMUX_CTIMER_IN:
 			mci_iomux->C_TIMER_IN |=
 				(0x1 << IOMUX_GET_CTIMER_BIT(pin_mux));
 			break;
 		case IOMUX_CTIMER_OUT:
 			mci_iomux->C_TIMER_OUT |=
 				(0x1 << IOMUX_GET_CTIMER_BIT(pin_mux));
 			break;
 		case IOMUX_SCTIMER_IN:
 			mci_iomux->SC_TIMER |=
 				(0x1 << IOMUX_GET_SCTIMER_BIT(pin_mux));
 			break;
 		case IOMUX_SCTIMER_OUT:
 			mci_iomux->SC_TIMER |=
 				(0x1 << (IOMUX_GET_SCTIMER_BIT(pin_mux) + 16));
 			break;
 		case IOMUX_SGPIO:
 			mci_iomux->S_GPIO |= (0x1 << (gpio_idx - 32));
 			break;
 		case IOMUX_GPIO:
 			if (gpio_idx > 32) {
 				mci_iomux->GPIO_GRP1 |= (0x1 << (gpio_idx - 32));
 			} else {
 				mci_iomux->GPIO_GRP0 |= (0x1 << gpio_idx);
 			}
 			break;
 		case IOMUX_AON:
 			/* No selection bits should be set */
 			break;
 		default:
 			/* Unsupported type passed */
 			return -ENOTSUP;
 		}
 		configure_pin_props(pin_mux, gpio_idx);
 		/* Now, enable pin controller access to this pin */
 		if (gpio_idx > 21 && gpio_idx < 28) {
 			/* GPIO 22-27 use always on soc controller */
 			iomux_en_reg = &aon_soc_ciu->MCI_IOMUX_EN0;
 		}
 		iomux_en_reg += (gpio_idx >> 5);
 		*iomux_en_reg |= (0x1 << (gpio_idx & 0x1F));
 	}
 	return 0;
 }
	/*
	* Copyright 2022 NXP
	*
	* SPDX-License-Identifier: Apache-2.0
	*/

	#include <zephyr/drivers/pinctrl.h>
	#include <soc.h>

	static MCI_IO_MUX_Type *mci_iomux =
	(MCI_IO_MUX_Type *)DT_REG_ADDR(DT_NODELABEL(pinctrl));

	static SOCCIU_Type *soc_ctrl =
	(SOCCIU_Type *)DT_REG_ADDR(DT_NODELABEL(soc_ctrl));
	static AON_SOC_CIU_Type *aon_soc_ciu =
	(AON_SOC_CIU_Type *)DT_REG_ADDR(DT_NODELABEL(aon_soc_ctrl));

	/*
	* GPIO mux option definitions. Stored as a static array, because
	* these mux options are needed to clear pin mux settings to
	* a known good state before selecting a new alternate function.
	*/
	static uint64_t gpio_muxes[] = {IOMUX_GPIO_OPS};

	/*
	* Helper function to handle setting pin properties,
	* such as pin bias and slew rate
	*/
	static void configure_pin_props(uint32_t pin_mux, uint8_t gpio_idx)
	{
	uint32_t mask, set;
	volatile uint32_t *pull_reg = &soc_ctrl->PAD_PU_PD_EN0;
	volatile uint32_t *slew_reg = &soc_ctrl->SR_CONFIG0;
	volatile uint32_t *sleep_force_en = &soc_ctrl->PAD_SLP_EN0;
	volatile uint32_t *sleep_force_val = &soc_ctrl->PAD_SLP_VAL0;

	/* GPIO 22-27 use always on configuration registers */
	if (gpio_idx > 21 && gpio_idx < 28) {
	pull_reg = (&aon_soc_ciu->PAD_PU_PD_EN1 - 1);
	slew_reg = (&aon_soc_ciu->SR_CONFIG1 - 1);
	sleep_force_en = &aon_soc_ciu->PAD_SLP_EN0;
	sleep_force_val = &aon_soc_ciu->PAD_SLP_VAL0;
	}
	/* Calculate register offset for pull and slew regs.
	* Use bit shifting as opposed to division
	*/
	pull_reg += (gpio_idx >> 4);
	slew_reg += (gpio_idx >> 4);
	sleep_force_en += (gpio_idx >> 5);
	sleep_force_val += (gpio_idx >> 5);
	/* Set pull-up/pull-down */
	/* Use mask and bitshift here as opposed to modulo and multiplication.
	* equivalent to ((gpio_idx % 16) * 2)
	*/
	mask = 0x3 << ((gpio_idx & 0xF) << 1);
	set = IOMUX_PAD_GET_PULL(pin_mux) << ((gpio_idx & 0xF) << 1);
	pull_reg = (pull_reg & ~mask) \| set;

	/* Set slew rate */
	set = IOMUX_PAD_GET_SLEW(pin_mux) << ((gpio_idx & 0xF) << 1);
	slew_reg = (slew_reg & ~mask) \| set;

	/* Set sleep force enable bit */
	mask = (0x1 << (gpio_idx & 0x1F));
	set = (IOMUX_PAD_GET_SLEEP_FORCE_EN(pin_mux) << (gpio_idx & 0x1F));
	sleep_force_en = (sleep_force_en & ~mask) \| set;
	set = (IOMUX_PAD_GET_SLEEP_FORCE_VAL(pin_mux) << (gpio_idx & 0x1F));
	sleep_force_val = (sleep_force_val & ~mask) \| set;
	}

	static void select_gpio_mode(uint8_t gpio_idx)
	{
	uint64_t gpio_setting = gpio_muxes[gpio_idx];
	volatile uint32_t *flexcomm_reg = &mci_iomux->FC0;

	/* Clear flexcomm settings */
	flexcomm_reg += IOMUX_GET_FLEXCOMM_CLR_IDX(gpio_setting);
	*flexcomm_reg &= ~IOMUX_GET_FLEXCOMM_CLR_MASK(gpio_setting);
	/* Clear fsel settings */
	mci_iomux->FSEL &= ~IOMUX_GET_FSEL_CLR_MASK(gpio_setting);
	/* Clear CTimer in/out, if required */
	if (IOMUX_GET_SCTIMER_IN_CLR_ENABLE(gpio_setting)) {
	mci_iomux->C_TIMER_IN &=
	~(0x1 << IOMUX_GET_CTIMER_CLR_OFFSET(gpio_setting));
	mci_iomux->C_TIMER_OUT &=
	~(0x1 << IOMUX_GET_CTIMER_CLR_OFFSET(gpio_setting));
	}
	/* Clear SCTimer in/out, if required */
	if (IOMUX_GET_SCTIMER_IN_CLR_ENABLE(gpio_setting)) {
	mci_iomux->SC_TIMER &=
	~(0x1 << IOMUX_GET_SCTIMER_IN_CLR_OFFSET(gpio_setting));
	}
	if (IOMUX_GET_SCTIMER_OUT_CLR_ENABLE(gpio_setting)) {
	mci_iomux->SC_TIMER &=
	~(0x1 << (IOMUX_GET_SCTIMER_OUT_CLR_OFFSET(gpio_setting) + 16));
	}
	/* Clear security gpio enable */
	mci_iomux->S_GPIO &= ~(0x1 << (gpio_idx - 32));
	}


	int pinctrl_configure_pins(const pinctrl_soc_pin_t *pins, uint8_t pin_cnt,
	uintptr_t reg)
	{
	volatile uint32_t *flexcomm_reg;
	volatile uint32_t *iomux_en_reg;

	for (uint8_t i = 0; i < pin_cnt; i++) {
	flexcomm_reg = &mci_iomux->FC0;
	iomux_en_reg = &soc_ctrl->MCI_IOMUX_EN0;
	uint32_t pin_mux = pins[i];
	uint8_t gpio_idx = IOMUX_GET_GPIO_IDX(pin_mux);
	uint8_t type = IOMUX_GET_TYPE(pin_mux);
	/*
	* Before selecting an alternate function, we must clear any
	* conflicting pin configuration. We do this by resetting the
	* pin to a gpio configuration, then selecting the alternate
	* function.
	*/
	select_gpio_mode(gpio_idx);
	switch (type) {
	case IOMUX_FLEXCOMM:
	flexcomm_reg += IOMUX_GET_FLEXCOMM_IDX(pin_mux);
	*flexcomm_reg \|=
	(0x1 << IOMUX_GET_FLEXCOMM_BIT(pin_mux));
	break;
	case IOMUX_FSEL:
	mci_iomux->FSEL \|=
	(0x1 << IOMUX_GET_FSEL_BIT(pin_mux));
	break;
	case IOMUX_CTIMER_IN:
	mci_iomux->C_TIMER_IN \|=
	(0x1 << IOMUX_GET_CTIMER_BIT(pin_mux));
	break;
	case IOMUX_CTIMER_OUT:
	mci_iomux->C_TIMER_OUT \|=
	(0x1 << IOMUX_GET_CTIMER_BIT(pin_mux));
	break;
	case IOMUX_SCTIMER_IN:
	mci_iomux->SC_TIMER \|=
	(0x1 << IOMUX_GET_SCTIMER_BIT(pin_mux));
	break;
	case IOMUX_SCTIMER_OUT:
	mci_iomux->SC_TIMER \|=
	(0x1 << (IOMUX_GET_SCTIMER_BIT(pin_mux) + 16));
	break;
	case IOMUX_SGPIO:
	mci_iomux->S_GPIO \|= (0x1 << (gpio_idx - 32));
	break;
	case IOMUX_GPIO:
	if (gpio_idx > 32) {
	mci_iomux->GPIO_GRP1 \|= (0x1 << (gpio_idx - 32));
	} else {
	mci_iomux->GPIO_GRP0 \|= (0x1 << gpio_idx);
	}
	break;
	case IOMUX_AON:
	/* No selection bits should be set */
	break;
	default:
	/* Unsupported type passed */
	return -ENOTSUP;
	}
	configure_pin_props(pin_mux, gpio_idx);
	/* Now, enable pin controller access to this pin */
	if (gpio_idx > 21 && gpio_idx < 28) {
	/* GPIO 22-27 use always on soc controller */
	iomux_en_reg = &aon_soc_ciu->MCI_IOMUX_EN0;
	}
	iomux_en_reg += (gpio_idx >> 5);
	*iomux_en_reg \|= (0x1 << (gpio_idx & 0x1F));
	}
	return 0;
	}